Weight scale utilizing a capacitative load cell

ABSTRACT

A platform weight scale comprising a capacitative load cell sensing means configured to be insensitive to off center loading of the horizontal platform regardless of load amount or location on the platform. The platform is supported by a plurality of springs selected for equal spring rates. The load cell is electrically connected into a FET (Field Effect Transistor), CMOS (Complementary Metal Oxide Semiconductor) or Bi-Polar semiconductor multivibrator circuit selected and designed to sense electric currents on the order of 10 -13  amperes. In one preferred embodiment the load cell comprises a grounded hemispherical surface opposing a flat charged plate. In alternate embodiments the load cell comprises a differential capacitor or a parallel plate capacitor suspended in a manner that is insensitive to off center loading. An additional embodiment for the load cell comprises a spherically concave surface opposing the above grounded hemispherical surface. 
     A method for two point calibration of the scale without the use of calibration weights is provided. The method provides for weighing the empty weight table or platform for the zero point, weighing the scale without the platform and without disassembly by turning upside down and then recalibrating the scale at the two points or settings. The differential capacitor load cell embodiment utilizes an alternatin switch circuit as a part of the multivibrator circuit. As a third alternative, a frequency modulated system clock circuit that is modulated by the load cell capacitance or differential capacitance may be utilized as the weight sensing circuit and driver for peripheral attachments to the scale circuit.

BACKGROUND OF THE INVENTION

This is a continuation-in-part of application Ser. No. 642,123, filed Aug. 17, 1984.

The field of the invention pertains to weight scales and, in particular, to electromechanical scales for weighing individual servings of food, however, the features of the scale are applicable to weighing ranges considerably greater or less than a range from fractions of an ounce to about a pound.

Typically, mechanical weighing means have utilized multiple lever arrangements and spring arrangements to move a dial indicator or balancing weight arm in response to the weight. More recently electric sensing means have been added for greater sensitivity and remote reading of the weight placed on the scale. The advent of miniaturized and sophisticated electronic circuitry in the form of integrated circuits at very low cost now permits sophisticated computations to be almost instantaneously performed in response to the input of the weight from weight sensing means in the scale and in response to other inputs to the electronic circuitry.

With the advent of the sophisticated and inexpensive electronic computational circuitry has developed a need for very inexpensive but highly accurate and sensitive electro-mechanical weight sensing means that can be fitted into the scale. The typical load cell, however, is expensive and cumbersome in comparison with the requirements of a simple, cheap but nevertheless computationally sophisticated and very accurate scale.

SUMMARY OF THE INVENTION

Applicant's scales disclosed in detail below utilize capacitive load cell sensing means configured to be insensitive to off center loading of the horizontal platform regardless of the load amount within the range of the scale or the location on the platform of the load. The platform is supported by a plurality of springs selected for equal spring rates and preferably located equidistant from and circumferentially about the platform. Although the preferred embodiments disclosed below utilize springs at the four corners of a rectangular platform, any number of springs about the platform from three to a continuous circumferential spring support may be utilized.

The capacitative load cell is connected electrically into a FET (Field Effect Transistor), CMOS (Complementary Metal Oxide Semiconductor) or Bi-Polar semiconductor multivibrator circuit selected and designed to sense electric currents on the order of 10⁻¹³ amperes. In one embodiment the load cell comprises a grounded hemispherical surface opposing a charged flat plate. In alternate embodiments the load cell comprises a grounded hemispherical surface opposing a charged spherically concave surface, a differential capacitor or a parallel plate capacitor suspended in a manner that is insensitive to off center loading of the platform. The differential capacitor load cell embodiment uitilizes an alternating switch circuit as a part of the multivibrator circuit.

In substitution for the multivibrator circuit a frequency modulated system clock circuit that is modulated by the load cell capacitance may be utilized as the weight sensing circuit and driver for the peripheral attachments to the scale circuit. Such attachments may suitably include a key pad, ROM (Read Only Memory), RAM (Random Access Memory) and display or printer.

The two point calibration method provides for weighing the scale by weighing the empty platform or table at the zero reading for the scale with the scale upright, and then placing the scale upside down and touching a calibration key or button on the keyboard of the scale. The internal programming for the scale rezeros the platform and compares the scale weight without the platform to the original scale weight without the platform when the scale was originally manufactured and calibrated to calculate a correction factor. Thus, the scale provides for internal two point recalibration without calibration weights.

DESCRIPTION OF THE DRAWINGS

FIG. 1 is a top view of the capacitative weight scale;

FIG. 2 is a partially cutaway side view of the weight scale;

FIG. 2a is a detail of an alternate means of supporting the scale platform;

FIG. 3 is a schematic side view of the unloaded platform and capacitor;

FIG. 4 is a schematic side view of the platform and capacitor with a center positioned load thereon;

FIG. 5 is a schematic side view of the platform and capacitor with an off-center positioned load thereon;

FIG. 6 is an electrical schematic of the internal circuitry for the weight scale;

FIG. 7 is a block diagram of the external circuitry and peripheral attachments for the weight scale;

FIG. 8 is a schematic side view of an alternate form of the platform and capacitor;

FIG. 8a is a detail for the additional electric circuitry for the alternate form of capacitor in FIG. 8;

FIG. 9 is a schematic side view of a second alternate form of the platform and capacitor;

FIG. 10 is a geometric illustration used for the explanation of the mathematical basis of the scale;

FIG. 11 is a top view of a low profile capacitative weight scale;

FIG. 12 is a side cross sectional view of the low profile weight scale of FIG. 11;

FIG. 13 is a side cross sectional view of an alternate form of the low profile weight scale of FIG. 11; and

FIG. 14 is a schematic side view of a third alternate form of the platform and capacitor.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Illustrated in FIGS. 1 and 2 is a weight scale employing a platform 10 suspended above a supporting box 12. The platform 10 is supported by four C-shaped brackets 14 at approximately the four corners of the platform 10. The brackets 14 are permanently affixed to the four upper corners of the box 12. Facing inwardly at each end of each bracket 14 are spring retainers 16. The coil spring retainers 16 each engage either upper 18 or lower 20 identical compression coil springs. The pairs of compression coil springs 18 and 20 at each corner of the platform 10 engage shallow sockets 22 formed in the upper and lower surfaces of the platform.

Attached to the underside of the platform 10 is a metal hemisphere 24. The hemisphere 24 is positioned at the center 26 of the platform 10 and each spring socket 22 is equidistant from the center 26. Located beneath the hemisphere 24 and supported within the box 12 is a metal flat plate 28 secured to an insulator that is driven by four lead screws. The box 12 top plate 30 is formed with a hole 32 above and somewhat larger than the flat plate 28. The metal hemisphere 24 extends into the hole 32 as shown to be in close proximity with the flat plate 28. For calibration purposes the flat plate 28 is moveable vertically by means of a lead screw or other conventional means to accurately raise and lower the flat plate. The calibration means include a rotatable dial indicator 34 extending from beneath the box 12. The dial indicator 34 is rotated to raise and lower the flat plate 28.

In the embodiment of FIGS. 1 and 2 the metal hemisphere 24 and flat plate 28 comprise a variable capacitor denoted by 25 in FIG. 6. The variable capacitance typically ranges from 10 to 20 pico-farads for a hemisphere of about one inch radius spaced from 0.0005 inches to 0.1 inches from the flat plate. The balance of the electric weighing circuit shown in FIG. 6 comprises an LF 311 Field Effect Transistor Comparator 36 supplied by National Semiconductor Corporation or equivalent. The passive external electric elements are as follows:

R1=2 megohm

R2=2 megohm

R3=1 megohm

R4=3.9 megohm

R5=1,000 ohm

VCC=5 volts

C2=0.1 micro farads

The circuit provides a free running multivibrator output at 38 which shifts in frequency (F0) in response to a changed capacitance 25.

Since the variable capacitance 25 is in the pico-farad range the circuit is located in a substantially air tight electrically shielded box or is plotted in an electrically shielded box beneath the flat plate 28. The shielded box also aids in maintaining thermal stability. The flat plate 28 is electrically insulated from the shielded box 12 of FIGS. 1 and 2 and connected to pin 3 of the comparator 36 in FIG. 6. The hemisphere 24 is connected to electrical ground, thus, in the embodiment of FIGS. 1 and 2 the hemisphere 24, platform 10 and metal box 12 are all grounded together to provide an electrical shield about the internal weighing circuit within the box 12.

The exterior of the box 12 is provided with a shielded socket 40 with which to connect a filtered 5 volt power supply to the weighing circuit and a shielded output socket 42 with which to connect the output 38 to a readout device or other attachment. As an example, in FIG. 7, the output 38 is connected (IRQ) to a 6502 Central Processing Unit (CPU) 44 available from several manufacturers and clocked by a crystal 46. The CPU in turn controls the display 48, read only memory (ROM) 50, random access memory (RAM) 52 and keyboard 54. The external circuit of FIG. 7 can be used to calculate various quantities based upon the output of the weighing circuit and information entered into the keyboard, e.g., calories per ounce for a piece of cake on the scale.

Returning to FIGS. 1 and 2 and as shown in FIGS. 3, 4 and 5, the scale is insensitive to the locational placement of a load on the platform 10. In assembling the spring pairs 18 and 20 at each corner of the platform 10, the springs are preloaded to put all of the springs within their linear range for best accuracy. As shown in FIG. 3 the hemisphere 24 is suspended a specific distance 56 above the flat plate 28. With a load 58 placed and centered at 26 as shown in FIG. 4, the platform 10 and hemisphere 24 move closer to the plate 28 as indicated by 56', compressed coil springs 20 and extended coil springs 18. The capacitance 25 changes to a new value, thus changing the output at 38 in FIG. 6.

In the event the same load 58 is not centered on the platform 10 as illustrated in FIG. 5, the platform 10 and hemisphere 24 tilt as shown in exaggeration. Although the platform 10 has tilted, the tilt is about the center 26 which moves downwardly toward plate 28 the same distance with the same load 58 as in FIG. 4. Thus, the distance 56" of the hemisphere 24 from the plate 28 is dependent only upon the load and not upon the location of the load on the platform. Therefore, the capacitance at 25 and output at 38 are likewise only dependent on the load and not a function of the location of the load on the platform.

The embodiment of FIGS. 1 and 2 is constructed of a solid metal box 12, platform 10 and a metal hemisphere 24. However, several alternative constructions that utilize less expensive materials can be substituted without compromising the electrical shielding and grounded exterior of the scale. Any or all of the exterior parts and the variable capacitance 25 can be constructed of a suitable plastic that can be plated with metal such as nickel or chrome. Thus, the box 12, platform 10, hemisphere exterior 24 and plate 28 can all be very inexpensively constructed of metal plated plastic. The metal plated box 12 and platform 10 thus comprise a very inexpensive means of shielding the sensitive circuitry within the box. Temperature sensitivity is also greatly lessened by the shielded box and platform.

The C-shaped brackets 14 can also be constructed from plated plastic or, as shown in FIG. 2a, the brackets 14 can be eliminated by substituting preloaded tension coil springs 120 for the compression springs 18. The tension springs 120 are preferably located inside and concentric with the compression springs 118 as illustrated. Small holes through the platform 110, socket 116 and top plate 130 accommodate fastening hooks 117 for the tension springs 120.

Illustrated in FIGS. 8 and 8a is a differential capacitor embodiment of the load cell. At the center of the platform 110 is affixed a ball and socket joint 126. Suspended from the ball and socket 126 is a piston rod 127 and a conductive piston 124 suitably made from graphite. The piston 124 is movable vertically in a cylinder 131 of non-conductive and non-magnetic material, such as unplated plastic or Pyrex brand glass. The cylinder 131 is closed at the lower end and provided with an orifice 135 sized to provide fluid damping for the scale platform.

Surrounding the cylinder 131 is a pair of conductive rings 128 and 128' which are electrically connected to a semiconductor dual switch (CMOS) such as an RCA CA 4016. The switch center connection 129 is connected to the oscillator input (3) of the LF 311 comparator and the switches are alternately connected to the rings 128 and 128' by the CPU 44 through circuits 133 and 133'.

The result of the alternating switch connection is a multiplexed oscillator input that changes in frequency from a midfrequency when the piston 124 is equidistant from the rings 128 and 128'. If the piston 124 and rings 128 and 128' are of the same conductive material, then temperature expansion of the load cell will not affect the overall ratios of the oscillator frequency about the mid-frequency. Thus, temperature compensation is inherent in the differential capacitative load cell.

In FIG. 9 the ball and socket 226 mounted at the center of the platform 210 supports a connecting rod 227 fastened to a plastic tube 231. Adhesively fastened to the lower end of the tube 231 is a flat non-magnetic conductive plate 224 which is electrically connected to ground. Within the plastic tube 231 is a downwardly pointed magnet 229 with the north pole at the tip. Beneath the plate 224 is a non-magnetic conductive plate 228 forming the charged side of the capacitive load cell. Centered beneath the plate 228 is a second pointed magnet 233 with the south pole at the tip. The magnets cause the plate 224 to remain horizontal and parallel with plate 228 despite tilting or unbalanced loading of the platform 210. In the configuration of FIG. 9 the lower plate 228 is connected into the circuit of FIG. 6 in the same manner as the embodiment of FIGS. 1 through 5.

FIG. 10 illustrates the geometry of the platform 310 upon which the mathematical analysis for the off center loading insensitivity is based. The sum of the four spring forces upwardly must equal the weight "W" or:

    F.sub.1 +F.sub.2 +F.sub.3 +F.sub.4 -W=0

The sum of the torques about any point on the platform must also equal zero, or:

    T.sub.1 +T.sub.2 +T.sub.3 +T.sub.4 +T.sub.w =0

where

    T.sub.1 =F.sub.1 ×D.sub.1, T.sub.2 =F.sub.2 ×D.sub.2, T.sub.3 =F.sub.3 ×D.sub.3, T.sub.4 =F.sub.4 ×D.sub.4 and T.sub.w =W×D.sub.w

And, "x" indicates a vector cross product.

Where the springs are matched, the spring constant "S" for all the springs is substantially identical. By symmetry it can be shown that F₁ +F₃ =F₂ +F₄ and in turn that the deflection at the center 326 of the platform is a function of the spring rate S and the weight W and is not a function of the distance D_(w) of the weight from the center of the platform. The analysis assumes that the forces F₁ through F₄ are always perpendicular to the platform. Owing to the small tilt of the platform in normal use, the assumption does not cause a significant error in measured weight.

Referring back to FIGS. 6 and 7 the LF 311 comparator may be eliminated by substituting a four bit micro-computer such as the NEC uPD 7503 or equivalent in place of the 6502 CPU. The system clock of the NEC uPD 7503 is timed by an external resistance and capacitance. Substitution of the variable weight sensing capacitance 25 for the clock creates a clock frequency that varies with the load on the scale platform. A second clock with the NEC uPD 7503 is formed by adding an external crystal to another micro-computer clock port to provide a constant frequency oscillator as a time reference in combination with the programmable counter of the computer.

The system clock with the variable frequency controls the time for a software routine to run a fixed number of instructions. At the end of the routine, the contents of the programmable counter above are read plus the number of times the counter overflowed. This number is a function of the capacitance 25 and therefore the load placed on the scale.

In a variation of the above technique, the number of times the programmable counter overflows is made constant and the number of instructions executed in that fixed time is counted. The number of instructions executed is thereby proportional to the system clock frequency and therefore a function of weight.

Illustrated in FIGS. 11 and 12 is a low profile capacitative weight scale employing the hemispherical variable capacitance. The scale includes a weighing table 408 rigidly affixed to a platform 410 therebelow by supports 409 passing through holes 407 in the top of the molded case or box 412 enclosing the workings of the scale. Within the case 412 and attached thereto by four vertically depending integral arms 411 are four brackets 414 located adjacent the four corners of the platform 410. Four lower coil springs 420 and four upper coil springs 418 suspend the platform 410 in the same manner as in the embodiment of FIGS. 1 and 2 above.

Affixed to the platform 410 and centered thereunder is a conductive hemisphere 424. Affixed to the bottom 413 of the case 412 is a conductive plate 428 below the hemisphere 424. The plate 428 is mounted on three or more headed studs 415 that pass through holes in the plate 428 and are affixed to the bottom 413. Light spiral springs 417 on each stud 415 urge the plate 428 against the heads of the studs 415 as illustrated. In normal operation of the scale, the spiral springs 417 retain the plate 428 against the stud heads without movement. In the event the scale is overloaded well beyond its design limit and the hemisphere 424 is forced down into contact with the plate 428, the plate 428 can be depressed enough without damage to permit the weighing table 408 to rest on the case 412. To prevent inadvertant electrical contact because of the overload, a Mylar layer or other insulative film may be coated on the plate 428 or hemisphere 424 over the conductive surfaces. The film will maintain the system clock in the event of an overload and contact of the hemisphere with the plate.

Sloping down from the weighing table 408 and fastened into apertures in the case 412 are a liquid crystal display 448 and a key pad 454. Beneath the key pad 454 and display 448 is a printed circuit board 419 fastened to the case 412 with most of the discrete components (not shown) thereon suspended from the board 419 downwardly. The microprocessor 444 is located on the foil side of the board 419. The key pad 454 is directly connected into the foil side of the board 419 in a conventional manner.

Refering to the modifications illustrated in FIG. 13, the weighing table 408 is supported on a platform 410' therebelow by shorter supports 409' which pass through holes 407 in the top of the molded case or box 412. The platform 410 rests upon four compression coil springs 420' in turn supported on pedestals 414' extending from the bottom 413 of the case 412.

Affixed to the platform 410' and centered thereunder is a conductive hemisphere 424' that is somewhat larger in radius that the hemisphere of FIG. 12. Below the hemisphere 424' is a conductive flat plate 428'. The plate 428' is mounted rigidly on three or more headed studs 415' that pass through holes in the plate 428'.

To prevent contact of the hemisphere 424' with the plate 428', the gap between the weighing table 408 and the top of the case 412 indicated at 457 is less than the gap 456 between the hemisphere 424' and the plate 428'. Thus, when the weighing table 408 rests upon the case 412 because of an overload, the hemisphere 424' is prevented from striking the plate 428.

The modified scale of FIG. 13 is of simpler construction than that of FIG. 12, however, the platform requires small studs 417' or other means to limit upward travel of the platform under unloaded conditions. Either form of the scale, however, can be constructed of plastic that is plated with an electrically conductive material on the inside or outside of the case. Thus, the electronic workings of the scale are protected from stray electric fields inadvertently applied to the scale and sudden outside temperature changes. In addition the conductive material also prevents radio frequency interference generated by the micro-computer from exceeding Federally mandated limits and causing Radio-TV interference.

FIG. 14 illustrates schematically a third alternate form of the platform and capacitor. The grounded portion of the capacitor is a convex hemisphere 524 affixed to the platform 510 and having an electrically conductive surface as above. Substantially concentric thereto is a concave spherical electrically conductive surface 528 insulated from but affixed to the supporting structure of the scale. This embodiment provides a relatively increased absolute capacitance in comparison to the hemisphere and flat plate capacitor of FIG. 3. Thus, this double spherical surface capacitor provides for a larger resolution or differential capacitance with a given vertical translational movement of the platform 510. The same insensitivity to rotational movement about the center 526 of the platform is retained.

The platform scale with a microprocessor control provides for the convenient addition of a self contained two point calibration method. The scale includes in a read-only memory (ROM) therein the zero point platfrom weight and the weight of the scale without the platform as manufactured.

To recalibrate, the empty platform is weighed and compared to the zero setting in the read-only-memory. The internal circuitry is then recalibrated to provide the zero reading. A recalibration code is then entered on the keyboard or "auto calibrate" button pushed and the scale is placed upside down to rest on the empty platform. The software compares the scale reading to the manufactured weight of the scale without the platform and recalibrates the internal circuitry to provide the correct reading at the second calibration point. Thus, two point calibration of the scale can be performed without the use of an additional calibration weight for the second calibration point.

A suitable method and algorithm for calibration at the first and second calibration points by obtaining the mathematical slope correction factor is as follows:

1. Compute initial count=turn on count and set scale display to zero;

2. Press "auto calibrate" button on keyboard to initiate count down from 10 to 0 and immediately turn scale upside down and rest on platform;

3. The scale will "beep" at "0" and

4. Compute count=turn on count-raw count;

5. Compute slopenum=(expected count *slopedenom)/count;

6. After second "beep", turn scale right side up;

7. Slopenum is applied by scale to subsequent weighings as follows:

8. Adjusted count (weight)=((turn on count-raw count) *slopenum)/slopedenom.

where:

a. "Count" is raw count when scale is weighed without platform during calibration.

b. "Raw Count" is oscillator count during weighing process.

c. "Turn on count" is oscillator count when scale turned on with zero weight on the platform.

d. "Slopenum"/"Slopedenom" is the slope correction factor and slopedenom is a constant.

e. "Expected count" is the original turn on count-raw count or factory calibration weight for the scale less platform.

f. "Adjusted count" or weight is weight corrected by the recalibration.

Thus, the scale can be recalibrated at the zero point and at the scale less the platform weight without calibration weights. 

We claim:
 1. A platform scale comprising a supporting structure, a platform on the supporting structure for movement relative to the supporting structure in response to a weight placed on the platform,spring means supporting and connecting the platform to the supporting structure, said spring means permitting both linear and rotational movement of the platform relative to the supporting structure, a variable capacitor comprising a portion of a substantially spherically convex surface affixed to the platform and having an electrically conductive surface, and adjacent thereto a substantially spherically concave surface affixed to the supporting structure and having an electrically conductive surface in opposition to the convex electrically conductive surface, wherein the center of the convex spherical surface is located substantially at the center of rotation of the platform, electrical means connected to the variable capacitor, said electrical means configured to sense a changed capacitance in the variable capacitor and in response thereto to provide an electrical output changed in response to the changed capacitance, and indication means connected to said electrical means and adapted to respond to the changed output with a changed display of information.
 2. The platform scale of claim 1 wherein at least one of the conductive surfaces comprises a conductive layer on a non-conductive substrate.
 3. The platform scale of claim 1 wherein at least one of the conductive surfaces includes an insulative layer thereover facing the other electrically conductive surface.
 4. The platform scale of claim 1 wherein the center of the spherically concave surface coincides with the center of the spherically convex surface when the platform is unloaded. 